Coupling1 of Aconitic Acid and Itaconic Acid with Certain Diazonium

The reaction of diazotized bases with unsaturated acids has now been extended to include aconitic and itaconic acids (R = CH2COOH). Irradiation of the...
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K. B. L. MATHUR, M. KRISHNAMURTI AND UPENDRA KUMARPANDIT

3240

[CONTRIBUTION FROM

THE

Vol. 7r,

DEPARTMENT O F CHEMISTRY, DELHIUNIVERSITY]

Coupling1of Aconitic Acid and Itaconic Acid with Certain Diazonium Chlorides BY K. B. L,MATHUR, M. KRISHNAMURTI AND UPENDRA KUMARPANDIT RECEIVED DECEMBER 7, 1951

Meerwein's diazo reaction2 with unsaturated acids of the type of maleic3 (R = H, CHa, Br) and acrylic4 (R = H, CH2) gives cinnamic acids ArNzCl

+ HOOC-CH=C(R)COOH

ArNzC1

+

= ArCH=C(R)COOH COZ CHpC(R)COOH = ArCH=C(R)COOH

+

+ NZ + HC1 + Nz + HCl

The reaction of diazotized bases with unsaturated acids has now been extended to include aconitic and itaconic acids (R = CH2COOH). Irradiation of the product obtained by the reaction of p-chlorobenzenediazonium chloride with aconitic acid gives 9-chlorophenylitaconic acid, a substance identical with that synthesized from p-

TABLE I ARYLITACONIC ACIDS,ArCH=C( C0OH)CHzCOOH Aro

Analyses, % Calcd. Found

Empirical formula

M.p., "C.

Neut. equiv. Calcd. Found

p-Chlorophenyl 193-194" CiiHsOaC1 C1 14.76 14.25 120.25 120 p-Nitrophenyl 193b CiiHaOsN K 558 5.62 125.5 128.4 m-Bromophenyl 174-175' CIIHBOIB~ Br . . . ... 142.5 142 p-Bromophenyl 200b'd C11HeO4Brz Br 28.00 27.5 142.5 144 The product (1.5 9.) deposited crystals from Et~O-CJT~, m.p. 161-163', having % C1 and neut. equiv. as for CiiHa04Cl; after irradiation gave m.p. above. 9-Chlorophenylitaconic acid was also synthesized from p-ClCsHd2H0, (CHzCO0Et)e and NaOEt as indicated. The initial sample (m.p. 170') after irradiation gave a product (Calcd. for C11HgO&l; C1, 14.7!; neut. equiv., 120.25. Found: C1, 14.4; neut. equiv., 120) having m.p. and mixed m.p. with above sample 192-193 . Working the oily products (1.5-2 g.) gave crystals (0.5-1 9.) of crude acids, the solvents retaining the oily mass. (%Br and neut. equiv. as for CllHgO4Br). 0 Products from diazotized aniline, m-nitro-, m-chloro-, o-bromoanilines were uncrystallizable oils. The oils and the acids in ammoniacal solutions gave precipitates with aqueous calcium or barium chloride. Crude m.p. 183-185". TABLE I1 WBENZYLACRYLIC ACIDS,ArCHzC( COOH)=CH* Product

Ar p-Chlorop henyl"

G.

M.p., OC.

Empirical formula

0.5

102

CioH90zC1

Analyses, Calcd.

C 61.0 H 4.6 C1 18.05

5%

Neut. equiv. Calcd. Found

Found

61.0 4.7 17.76

196.5

196

... ... 162 158 Phenyl' Few drops crude 68 CmHloOz o-Chlorophenyl 0.8 90 ClaH902Cl C1 18-05 17.90 196.5 190 @-Bromophenyl' 1.2 119 Cl&IsOeBr Br 33.2 32.7 24 1 243 p-Nitrophenyld 0.92 142 Ci&I904N N 6.76 6.49 207 213 The acid (0.2 g.) in CHC13(10 ml.) and Br (0.5 ml.) yielded the dibromide, crystallized from AcOH.&O ( 1 : l ) in c u b s , AgBr, 0.3516 g.; calcd. for CloHgO?ClBrZ,AgCl AgBr, 0.3596.g.). Polym.p. 150' (Found: 0.2468 g. gave AgCl merized when impure or in presence of HCl; dibromide, m.p. 143', identical with that of a-benzylacryhc acid (wide J. L. Polymerized on prolonged treatment Simonsen, J . Chem. Sac., 117, 568 (1920)). c Polymerized withcoldconcd. with hot concd. HCl or upon heating its sodium salt a t 250" for 2 hours.

+

+

TABLE I11 Acids

M.p., "C.

Analyses, % Calcd. Found

Empirical formula

Neut. equiv. Calcd. Found

199 c1oH,0,c1 C1 15.67 15.2 113.25 111 157 CioHgOKl C1 15.53 15.3 114.25 112.5 Piperidinomethyl-p-chlorobenzylmalonicb 162 CiaHzoNO4Cl c1 10.9 11.2 162.7 162 a-p-Chlorobenzylacrylicd 102 CIoHg02C1 C1 18.05 18.28 195.5 195 a-p-Chlorobenzylacrylic dibromidecvd 151 CloHgOzCIBrz Br 44.88 45.26 .... ... The piperidine acid salt ( 2 g.), formalin (7 ml.) upon refrigeration yielded a solid. Its (solid) alkaline extract upon Piperiacidification gave piperidinomethyl-p-chlorobenzylmalonicacid, puritied by washing with water and then alcohol. dinomethyl-p-chlorobenzylmalonicacid (1.5 g.), hydroquinone (few crystals) were heated (150-170") under slight vacuum 0.2644 g. gave AgCl AgBr, 0.3798 g. for '/z hour. The aq. NaHCOI extract contained a-p-chlorobenzylacrylic acid. M.p.'s remained undepressed with materials prepared as above, respectively. (calcd. 0.3854 g . ) . p-Chlorobenzalmalonic

p -Chlorobenzylmalonic"

+

(1) Based on Paper No. 31 (Organic Section), XIIth International Congress of Pure and Applied Chemistry, New York (1951). Publication delayed by manuscript loss and transit mishap. (2) (a) V. H.Meerwein, E. Buchner and K. van Emster, J . $44. Chcm., 153, 237 (1939); (b) cf. also C. F. Koelsch and V. Boekelheide, THIS JOURNAL, 66, 412 (1944). (3) (a) D. R. Dhingra and K. B. L. Mathur, J . Indian Chcm. Soc., '24, 123 (1947); (b) cf. J. Rai and K. B. L. Matbur, ibid., 34, 383 (1947); (c) Sain Dass and K. B. L. Mathur, ibid., 38, 540 (1951). (4) (a) J. Rai and K. B. L. Mathur, ibid., '24, 413 (1947): (b) M. Krishnamurti and K. B. L. Mathur, i b i d . , 28, 507 (1951).

chlorobenzaldehyde and diethyl succinate in the presence of sodium ethoxide? Before irradiation, the product appears to be a mixture of p-chlorophenylitaconic acid and the 9-chlorophenylaticonic acid. Analogous products have been obtained from three other diazotized bases.

+

ArX,C1 HOOC-CH=C( C0OH)CHzCOOH = Ar-CH=C(COOH)CHzCOOH COz NZ ___

+

+ + HC1

( 6 ) C f IIans Stobbe, Bcr., 41, 4353 (1908), for the parent acid.

ADDITION REACTIONS TO ETHYL~,~,-~TRIFLIJOROCROTONATE 3241

July 5, 1953

The reaction of p-chlorobenzenediazonium chloride with itaconic acid gives an unsaturated monobasic acid, identified as a-$-chlorobenzylacrylic acid by the following synthesis : p-Chlorobenzalmalonic acid was reduced to D-chlorobenzylmalonic acid,Oa which was converted by the Mannich reaction (with piperidine and formaldehyde) into piperidinomethyl - p - chlorobenzylmalonic acid, which was in turn pyrolyzedBbto give a-p-chlorobenzylacrylic acid. CaHioSCHz-C(COOH)zCHzC~H~Cl= CHFC( CO0H)CHzCeHaCl

+ C6HioNH + COz

Itaconic acid reacts with other diazotized bases in the same way. ArNzCl

+ CHZ=C(COOH)CHZCOOH = ArCHz-C(COOH)=CHz + COZ+ NZ + HCl

In the above reactions, presumably initiated by a chain m e c h a n i ~ m , the ~ ~ ?transient ~~ formation of the ion (R‘CHAr-C(COOH)CH2COOH) is postu-

+

lated, followed by the loss of carbon dioxide and hydrogen ion. When R’ is COOH, the final product is an itaconic acid; when R‘ is hydrogen, the final product is an acrylic acid. Thus, the diazo (6) For the parent acids: cf. (a) L. Claisen and L. Crismer, Ann., 118, 139 (1883); (b) C.Mannich and E. Gaaz, Bey., 55, 3495 (1922).

reaction with both acanitic and itaconic acids involves decarboxylation.

Experimental Coupling Reactions.-The amine (0.025 mole) dissolved in 6 ml. of warm concd. hydrochloric acid, diluted with 10 ml. of water, then cooled with 5 g. of crushed ice. was diazotized by addition of sodium nitrite (0.025 mole) in 7 ml. of water. The diazo solution was added with stirring to the acid, aconitic or itaconic (0.025 mole), 1 g. of cupric chloride and 5.75 g. of sodium acetate in 20 ml. of water. The temperature was kept a t 30-35’. Brisk effervescence usually followed. After standing overnight, the products were isolated from the solid or semi-solid matter that had separated by extraction with 10% aqueous sodium bicarbonate and acidification with dilute hydrochloric acid. The precipitated acids from aconitic acid were oils. However, in several cases concentration of their solutions in ether-benzene (1 : 1) yielded crystals. Upon irradiation (about two hours) with traces of bromine in ether-chloroform, removal of the solvent, and recrystallization from hot water, the melting point rose t o that of the aryl itaconic acid (Table I). The products from itaconic acid were a-benzylacrylic acids (Table 11),crystallized from water. a-9-Chlorobenzylacrylic acid and its dibromide were synthesized by another route as described. The relevant details, including those for the intermediates, are shown in Table 111.

.

The authors desire to thank Prof. T. R. Seshadri for his interest in this work. DELHI,INDIA

[CONTRIBUTION FROM THE DEPARTMENT O F CHEMISTRY, THEFLORIDA STATE UNIVERSITY]

Addition Reactions to Ethyl r,r,r-Trifluorocrotonate BY HARRYM. WALBORSKY AND MEYERSCHWARZ RECEIVEDFEBRUARY 23, 1953 The preparation of ethyl r,r,r-trifluorocrotonate is reported. The addition of unsymmetrical reagents to the double bond is investigated and it is demonstrated that the CFs group does not reverse the normal mode of addition. The dissociation constant of -y,r,y-trifluorocrotonic acid is 7.1 & 0.1 X 10-4.

The direction of addition of unsymmetrical reagents to ethyl y,y,y-trifluorocrotonate was of interest in order to determine whether the trifluoromethyl group or the carbethoxy group would be the controlling factor. In the former case, the trifluoromethyl group might be expected to direct the entering anion to the a-carbon atom through an inductive or hyperconjugative effect1 as illustrated in I. If the carbethoxy group were more important, the nucleophilic reagent would react at the ,&position. The determining factor would thus be the resonance stabilization produced by interaction of the carbethoxy group with the double bond (11). 0 F- C F ~ C H - ~ H C ~ \OEt

I

+

CFs-CH-CH---

IT

Henne and co-workers2 have shown that ionic addition (both acid- and base-catalyzed) as well as radical addition of unsymmetrical reagents to 3,3,3-trifluoropropene yields exclusively “antiMarkovnikow” products. Thus the addition of hydrogen bromide produced 1,1,l-trifluoro-3(1) N. Haszeldiae, J . Chcm. Soc., 3483 (1952). (2) A. Henne, e1 ol.. THISJOURNAL, 72, 3369, 4766 (1950); ‘IS, 5527 (1951).

bromopropane. In this case the CFs group polarized the double bond so that the terminal carbon atom possessed the lowest electron density. The strong polarizing effect of the CF3 group was clearly demonstrated. On the other hand, it is well known that when one adds hydrogen i ~ d i d ehydrogen ,~ bromide,3 alcohol4 and ammonia6 to ethyl crotonate, the nucleophilic attack of these unsymmetrical reagents is directed a t the @-carbonatom to yield &substituted derivatives of ethyl butyrate. The system under investigation, ethyl y , y , y trifluorocrotonate, was prepared by the dehydration of ethyl /3-hydroxy-y, y , y-trifluorobutyrate. The dehydration of alcohols which have a trifluoromethyl group adjacent to the carbon atom containing the hydroxyl group, has been described as difficult.6 Conventional methods of dehydration (potassium acid sulfate or concd. sulfuric acid) gave no unsaturated products. The yield using phosphorus pentoxide was too low for preparative use. The carbinol was finally converted to the (3) W.Hemilian, Ann., 174, 324 (1874). J. C h e n . Soc., 59, 478 (1891). (5) K.Morsch, Monarsh., 60,50 (1932). (6) R. Campbell, J , Kaobloch and B. Campbell, THISJOURNAL, 71, 4380 (1950). (4) Purdie and Marshall,